“Do-it-yourself biology” is a metaphor referring to the prospect of amateurs creating organisms in their kitchen or garage. Imagine a world where anybody with an average IQ has the ability to create novel organisms in their home garage without adhering to professional code or conduct, adhering to safety regulations, and lacking sufficient biosafety training. On one hand, the promise of DIY Biology movement opens up biology to potentially create the next Silicon Valley. They are Steve Jobs and Bill Gates of the mid-1970’s or the Mark Zuckerberg of early 2000’s. Imagine just before the PC or social media explosions. On the other hand, DIY biologist are tampering with living organisms and if they aren’t careful they could release virulent bugs that could lead to harm. Is there an economic miracle or a doomsday situation just around the corner? The enthusiasm for DIY Biology as a “movement” is relatively recent, beginning around 2005, and has been popularized by Make Magazine, published by O’Reilly Media which has traditionally focused on do-it-yourself projects involving computers, electronics, and robotics. The International Genetically Engineered Machine (iGEM) competition has contributed to the growth of the DIY biology movement by making standard components and kits available to a large community. To date, universities have focused on using the concepts of DIY biology for educating and teaching, scholarly publications have focused on the ethics and biosafety ramifications. While DIY biologist want to revise the notation that you require and advanced degree to make a significant contribution to biology, traditional scientist have legitimate concerns for safety, legal, and ethical issues.

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“Do-it-yourself biology” is a metaphor referring to the prospect of amateurs creating organisms in their kitchen or garage. Imagine a world where anybody with an average intelligence has the ability to create new organisms in their home garage without adhering to professional code or conduct, adhering to safety regulations, and lacking sufficient biosafety training.

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==References==

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On one hand, the promise of DIY Biology movement opens up biology to potentially create the next Silicon Valley. They are Steve Jobs and Bill Gates of the mid-1970’s or the Mark Zuckerberg of early 2000’s. Imagine just before the PC or social media explosions. On the other hand, DIY biologist are tampering with living organisms and if they aren’t careful they could release virulent bugs that could lead to harm.

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Is there an economic miracle or a doomsday situation just around the corner? The enthusiasm for DIY Biology as a “movement” is relatively recent, beginning around 2005, and has been popularized by Make Magazine, published by O’Reilly Media which has traditionally focused on do-it-yourself projects involving computers, electronics, and robotics. The International Genetically Engineered Machine (iGEM) competition has contributed to the growth of the DIY biology movement by making standard components and kits available to a large community. To date, universities have focused on using the concepts of DIY biology for educating and teaching, scholarly publications have focused on the ethics and biosafety ramifications.

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While DIY biologist want to revise the notation that you require and advanced degree to make a significant contribution to biology, traditional scientist have legitimate concerns for safety, legal, and ethical issues.

#[http://www.amazon.com/The-Innovators-Dilemma-Revolutionary-Business/dp/0062060244/ref=sr_1_1?ie=UTF8&qid=1359572188&sr=8-1&keywords=innovators+dilemma C. Christensen, The Innovator's Dilemma: When New Technologies Cause Great Firms to Fail, Harvard Business Press, 1997]

#[http://www.amazon.com/The-Innovators-Dilemma-Revolutionary-Business/dp/0062060244/ref=sr_1_1?ie=UTF8&qid=1359572188&sr=8-1&keywords=innovators+dilemma C. Christensen, The Innovator's Dilemma: When New Technologies Cause Great Firms to Fail, Harvard Business Press, 1997]

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==What will it take for DIY Biology Adoption more Broadly?==

==What will it take for DIY Biology Adoption more Broadly?==

Many factors must come together to see DIY Biology become a real broad based movement. Given the obstacles, DIY Biology may initially find a niche in education applications.

Many factors must come together to see DIY Biology become a real broad based movement. Given the obstacles, DIY Biology may initially find a niche in education applications.

#Low-cost equipment & processes – low-cost DIY Biology Instrumentation (PCR, centrifuges . . .) become accepted in university as low-cost alternatives in research labs and are seen as being "good enough"

#Community & curator – a company or university creates approved “deployment” targets (organism and hardware). Low cost 3D printing may provide a source for deployment microfluidic hardware. Standardization occurs with respect to the bacteria used for design and deployment of synthetic biology based designs. The curator provides safety and ethical oversight.

#IP protection and infrastructure investment

#IP protection and infrastructure investment

#Feedback – something beyond a ‘star’ rating, peer reviewed ratings

#Feedback – something beyond a ‘star’ rating, peer reviewed ratings

#Killer App – A 'killer app' that the masses can easily identify with could spur on innovation and acceptance. Most likely the source of the killer app will come from a market that has less restrictive regulations which will create a lower barrier of entry (home brewers is DIY Biology)

#Killer App – A 'killer app' that the masses can easily identify with could spur on innovation and acceptance. Most likely the source of the killer app will come from a market that has less restrictive regulations which will create a lower barrier of entry (home brewers is DIY Biology)

Current revision

Contents

Introduction

“Do-it-yourself biology” is a metaphor referring to the prospect of amateurs creating organisms in their kitchen or garage. Imagine a world where anybody with an average intelligence has the ability to create new organisms in their home garage without adhering to professional code or conduct, adhering to safety regulations, and lacking sufficient biosafety training.

On one hand, the promise of DIY Biology movement opens up biology to potentially create the next Silicon Valley. They are Steve Jobs and Bill Gates of the mid-1970’s or the Mark Zuckerberg of early 2000’s. Imagine just before the PC or social media explosions. On the other hand, DIY biologist are tampering with living organisms and if they aren’t careful they could release virulent bugs that could lead to harm.

Is there an economic miracle or a doomsday situation just around the corner? The enthusiasm for DIY Biology as a “movement” is relatively recent, beginning around 2005, and has been popularized by Make Magazine, published by O’Reilly Media which has traditionally focused on do-it-yourself projects involving computers, electronics, and robotics. The International Genetically Engineered Machine (iGEM) competition has contributed to the growth of the DIY biology movement by making standard components and kits available to a large community. To date, universities have focused on using the concepts of DIY biology for educating and teaching, scholarly publications have focused on the ethics and biosafety ramifications.

While DIY biologist want to revise the notation that you require and advanced degree to make a significant contribution to biology, traditional scientist have legitimate concerns for safety, legal, and ethical issues.

DIY Biology: Issues and Insights Summary

What are the safety, ethical, and legal issues especially for designed microorganisms?

DIY Biology has the potential to have an economic impact and be a source of innovation.

For DIY Biology innovations is there an issue of legitimacy, or how does it become accepted?

Do we need a new "construct" for how the public can participate in biological research and innovation?

What will it take for DIY Biology Adoption more Broadly?

Many factors must come together to see DIY Biology become a real broad based movement. Given the obstacles, DIY Biology may initially find a niche in education applications.

Tool chain standardization and abstraction – further abstraction of design tools (i.e. Biobricks). It must become easier to create novel designs.

More reliable design elements – synthetic biology component's outputs and actions must be more predictable like electronic components.

Low-cost equipment & processes – low-cost DIY Biology Instrumentation (PCR, centrifuges . . .) become accepted in university as low-cost alternatives in research labs and are seen as being "good enough"

Community & curator – a company or university creates approved “deployment” targets (organism and hardware). Low cost 3D printing may provide a source for deployment microfluidic hardware. Standardization occurs with respect to the bacteria used for design and deployment of synthetic biology based designs. The curator provides safety and ethical oversight.

IP protection and infrastructure investment

Feedback – something beyond a ‘star’ rating, peer reviewed ratings

Killer App – A 'killer app' that the masses can easily identify with could spur on innovation and acceptance. Most likely the source of the killer app will come from a market that has less restrictive regulations which will create a lower barrier of entry (home brewers is DIY Biology)